Enzyme Structure, Classification, and Mechanism of Action

1. Enzyme Structure, Classification and Mechanism of Action DR. ARNEL BANAGA SALGADO,Psy.D., FMP (Psychology), Ed.D., Sc.D., RN, PGD H/P No.: 050-799-3803 URL: www.ifeet.org; www.arnelsalgado.com • Member: Sigma Theta Tau International – Honor Society of Nursing (Constituent No. 1628977) • Member: American Psychological Association (APA Roll No. 04438162) • Doctor of Psychology (Psych.D.) • Fellow Program in Management (FPM – Psychology) • Doctor of Science (D.Sc.) • Doctor of Education (Ed.D.) • Master of Arts in Nursing (M.A.N) • Master of Arts in Teaching - Psychology (M.A.T.) • Registered Nurse (PH, MYL, UAE) • Licensed Teacher (PH) • Certificate in Teaching, • Bachelor of Science in Nursing (BSN, PH)

2. Learning Objectives: At the end of the lesson, the students should be able to : • Define enzymes and related terms (active site, apoenzyme, holoenzyme, prosthetic group, enzyme specificity). • Explain the energy of activation. • Describe the structure of enzymes. • Know the Mechanism of action • Explain the Classification of enzymes Lecture No. 3 Enzyme Structure, classification and mechanism of action

3. Importance Enzymes play an important role in Metabolism, Diagnosis, and Therapeutics. All biochemical reactions are enzyme catalyzed in the living organism. Level of enzyme in blood are of diagnostic importance e.g. it is a good indicator in disease such as myocardial infarction. Enzyme can be used therapeutically such as digestive enzymes. Lecture No. 3 Enzyme Structure, classification and mechanism of action

4. Define enzymes (Enzymes as Biological Catalysts) • Enzymes are proteins that increase the rate of reaction by lowering the energy of activation • They catalyze nearly all the chemical reactions taking place in the cells of the body. • Not altered or consumed during reaction. • Reusable Lecture No. 3 Enzyme Structure, classification and mechanism of action

5. ACTIVE SITES • Enzyme molecules contain a special pocket or cleft called the active sites. Lecture No. 3 Enzyme Structure, classification and mechanism of action

6. Lock-and-Key Model In the lock-and-key model of enzyme action: - the active site has a rigid shape - only substrates with the matching shape can fit - the substrate is a key that fits the lock of the active site This explains enzyme specificity This explains the loss of activity when enzymes denature Lecture No. 3 Enzyme Structure, classification and mechanism of action

7. APOENZYME and HOLOENZYME • The enzyme without its non protein moiety is termed as apoenzyme and it is inactive. • Holoenzyme is an active enzyme with its non protein component. Lecture No. 3 Enzyme Structure, classification and mechanism of action

8. Important Terms to Understand Biochemical NatureAnd Activity of Enzymes • Cofactor: • A cofactor is a non-protein chemical compound that is bound (either tightly or loosely) to an enzyme and is required for catalysis. • Types of Cofactors: • Coenzymes. • Prosthetic groups. Lecture No. 3 Enzyme Structure, classification and mechanism of action

9. Types of Cofactors • Coenzyme:The non-protein component, loosely bound to apoenzyme by non-covalent bond. • Examples : vitamins or compound derived from vitamins. • Prosthetic groupThe non-protein component, tightly bound to the apoenzyme by covalent bonds is called a Prosthetic group. Lecture No. 3 Enzyme Structure, classification and mechanism of action

10. Enzyme Specificity • Enzymes have varying degrees of specificity for substrates • Enzymes may recognize and catalyze: - a single substrate - a group of similar substrates - a particular type of bond Lecture No. 3 Enzyme Structure, classification and mechanism of action

11. Lecture No. 3 Enzyme Structure, classification and mechanism of action

12. Important Terms to Understand Biochemical NatureAnd Activity of Enzymes Activation energy or Energy of Activation: All chemical reactions require some amount of energy to get them started. OR It is First push to start reaction. This energy is called activation energy. Lecture No. 3 Enzyme Structure, classification and mechanism of action

13. Mechanism of Action of Enzymes • Enzymes increase reaction rates by decreasing the Activation energy: • Enzyme-Substrate Interactions: • Formation of Enzyme substrate complex by: • Lock-and-Key Model • Induced Fit Model Lecture No. 3 Enzyme Structure, classification and mechanism of action

14. Enzymes Lower a Reaction’s Activation Energy Lecture No. 3 Enzyme Structure, classification and mechanism of action

15. Lecture No. 3 Enzyme Structure, classification and mechanism of action

16. Lock-and-Key Model In the lock-and-key model of enzyme action: - the active site has a rigid shape - only substrates with the matching shape can fit - the substrate is a key that fits the lock of the active site This is an older model, however, and does not work for all enzymes Lecture No. 3 Enzyme Structure, classification and mechanism of action

17. Induced Fit Model In the induced-fit model of enzyme action: - the active site is flexible, not rigid - the shapes of the enzyme, active site, and substrate adjust to maximumize the fit, which improves catalysis - there is a greater range of substrate specificity This model is more consistent with a wider range of enzymes Lecture No. 3 Enzyme Structure, classification and mechanism of action

18. Enzyme-substrate complex • Step 1: • Enzyme and substrate combine to form complex • E + S ES • Enzyme Substrate Complex + Lecture No. 3 Enzyme Structure, classification and mechanism of action

19. Enzyme-product complex • Step 2: • An enzyme-product complex is formed. • ES EP transition state ES EP Lecture No. 3 Enzyme Structure, classification and mechanism of action

20. EP Product • The enzyme and product separate • EPE + P The product is made Enzyme is ready for another substrate. Lecture No. 3 Enzyme Structure, classification and mechanism of action

21. What Affects Enzyme Activity? Three factors: 1. Environmental Conditions 2. Cofactors and Coenzymes 3. Enzyme Inhibitors Lecture No. 3 Enzyme Structure, classification and mechanism of action 25

22. 1. Environmental Conditions 1. Extreme Temperature are the most dangerous - high temps may denature (unfold) the enzyme. 2. pH (most like 6 - 8 pH near neutral) 3. substrate concentration . Lecture No. 3 Enzyme Structure, classification and mechanism of action 26

23. 2. Cofactors and Coenzymes Inorganic substances (zinc, iron) and vitamins (respectively) are sometimes need for proper enzymatic activity. Example: Iron must be present in the quaternary structure-hemoglobin in order for it to pick up oxygen. Lecture No. 3 Enzyme Structure, classification and mechanism of action 27

24. Environmental factors Optimum temperature The temp at which enzymatic reaction occur fastest. Lecture No. 3 Enzyme Structure, classification and mechanism of action

25. Environmental factors • pH also affects the rate of enzyme-substrate complexes • Most enzymes have an optimum pH of around 7 (neutral) • However, some prefer acidic or basic conditions Lecture No. 3 Enzyme Structure, classification and mechanism of action

26. Substrate Concentration and Reaction Rate The rate of reaction increases as substrate concentration increases (at constant enzyme concentration) Maximum activity occurs when the enzyme is saturated (when all enzymes are binding substrate) Lecture No. 3 Enzyme Structure, classification and mechanism of action

27. Enzyme Inhibitors • Competive - mimic substrate, may block active site, but may dislodge it. Lecture No. 3 Enzyme Structure, classification and mechanism of action

28. Enzyme Inhibitors • Noncompetitive Lecture No. 3 Enzyme Structure, classification and mechanism of action

29. Naming Enzymes • The name of an enzyme in many cases end in –ase • For example, sucrase catalyzes the hydrolysis of sucrose • The name describes the function of the enzyme For example, oxidasescatalyze oxidation reactions • Sometimes common names are used, particularly for the digestion enzymes such as pepsin and trypsin • Some names describe both the substrate and the function • For example, alcohol dehydrogenase oxides ethanol Lecture No. 3 Enzyme Structure, classification and mechanism of action

30. Enzymes Are Classified into six functional Classes (EC number Classification) by the International Union of Biochemists (I.U.B.).on the Basis of the Types ofReactions That They Catalyze EC 1. Oxidoreductases EC 2. Transferases EC 3. Hydrolases EC 4. Lyases EC 5. Isomerases EC 6. Ligases Lecture No. 3 Enzyme Structure, classification and mechanism of action

31. Principle of the international classification Each enzyme hasclassification number consisting of four digits: Example, EC: (2.7.1.1) HEXOKINASE Lecture No. 3 Enzyme Structure, classification and mechanism of action

32. EC: (2.7.1.1) these components indicate the following groups of enzymes: 2. IS CLASS (TRANSFERASE) 7. IS SUBCLASS (TRANSFER OF PHOSPHATE) 1. IS SUB-SUB CLASS (ALCOHOL IS PHOSPHATE ACCEPTOR) 1. SPECIFIC NAME ATP,D-HEXOSE-6-PHOSPHOTRANSFERASE (Hexokinase) Lecture No. 3 Enzyme Structure, classification and mechanism of action

33. 1. Hexokinase catalyzes: Glucose + ATPglucose-6-P + ADP Lecture No. 3 Enzyme Structure, classification and mechanism of action

34. Oxidoreductases, Transferases and Hydrolases Lecture No. 3 Enzyme Structure, classification and mechanism of action

35. Lyases, Isomerases and Ligases Lecture No. 3 Enzyme Structure, classification and mechanism of action